自然和瞬态强制通风中庭火灾的弗劳德缩放模型

IF 1.1 4区工程技术 Q3 CONSTRUCTION & BUILDING TECHNOLOGY

International Journal of Ventilation Pub Date : 2020-07-02 DOI:10.1080/14733315.2019.1615220

Mohsen M. Barsim, M. Bassily, H. El-Batsh, Yaser A. Rihan, M. M. Sherif

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引用次数: 8

摘要

摘要本文分别利用全尺寸中庭和CFX-Ansys16.2的2:27物理缩小模型(SDM)，研究了Froude缩放模型在自然和瞬态强制通风条件下模拟全尺寸Murcia中庭火灾的能力。采用位于地板中心的不同庚烷火容进行了5次SDM实验。采用剪切应力输运和k−ε两种不同的湍流模型进行模拟。通过保留弗劳德数，将SDM和全尺寸中庭火灾实验结果与SDM的预测结果进行比较，以弥补实验事实和科学认识上的差距。本文主要研究了近、远火场的瞬态温度和降烟层。对预测速度和能见度进行了评估。本研究表明，当阈值大于全尺寸的50%时，弗劳德缩放模型是可以接受的。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Froude scaling modeling in an Atrium Fire equipped with natural and transient forced ventilation

Abstract In this paper, the capability of Froude scaling modeling to replicate the fire dynamics in full-scale Murcia Atrium Fires tests equipped with natural and transient forced ventilation was investigated experimentally and numerically by using a 2:27 physical Scale Down Model (SDM) of the full-scale Atrium and CFX-Ansys16.2, respectively. Five SDM experiments were conducted using different heptane fire capacities located at the center of the floor. Two different turbulence models were used for simulation i.e. Shear Stress Transport and k − ε. Experimental results of the SDM and full-scale atrium fire tests were compared with those predicted for SDM through the preservation of the Froude number to cover the gap in experimental facts and scientific understanding. This study focused primarily on the transient temperatures at near and far fire fields and the descending smoke layer. The predicted velocity and visibility were assessed. This study demonstrated that Froude scaling modelling is acceptable from a threshold of greater than 50% of the full-scale.

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来源期刊

International Journal of Ventilation CONSTRUCTION & BUILDING TECHNOLOGY-ENERGY & FUELS

CiteScore

3.50

自引率

6.70%

发文量

审稿时长

>12 weeks

期刊介绍： This is a peer reviewed journal aimed at providing the latest information on research and application. Topics include: • New ideas concerned with the development or application of ventilation; • Validated case studies demonstrating the performance of ventilation strategies; • Information on needs and solutions for specific building types including: offices, dwellings, schools, hospitals, parking garages, urban buildings and recreational buildings etc; • Developments in numerical methods; • Measurement techniques; • Related issues in which the impact of ventilation plays an important role (e.g. the interaction of ventilation with air quality, health and comfort); • Energy issues related to ventilation (e.g. low energy systems, ventilation heating and cooling loss); • Driving forces (weather data, fan performance etc).